| Allotriomorphic and Idiomorphic Ferrite in Steels: Introduction |
| Arrangement of atoms in ferrite (a form of iron) |
| Atomic Mechanism of the Bainite Transformation in Steels |
| Bainite and Widmanstatten ferrite in steels |
| Carbon atom in octahedral interstice in ferrite in steel |
| Carbon atom in tetrahedral interstice in Austenite in Steel |
| Carbon atom in tetrahedral interstice in austenite in steel |
| Carbon in crystal structure of austenitic iron |
| Carbon in crystal structure of austenitic iron |
| Cementite in steels |
| Cementite in steels: crystallography |
| Characteristics of Martensite in Steels |
| Coincidence Site Lattice - a model for interfaces |
| Computer Calculation of Phase Diagrams |
| Creep Resistant Steels |
| Crystal structure of austenite |
| Crystallography: Cubic-F lattice |
| Crystallography: Cubic-I lattice. One of the 14 Bravais lattices |
| Crystallography: Cubic-P lattice. One of the 14 Bravais lattices |
| Crystallography: Hexagonal lattice. One of the 14 Bravais lattices |
| Crystallography: Monoclinic-C lattice. One of the 14 Bravais lattices |
| Crystallography: Monoclinic-P lattice. One of the 14 Bravais lattices |
| Crystallography: Orthorhombic-C lattice. One of the 14 Bravais lattices |
| Crystallography: Orthorhombic-F lattice. One of the 14 Bravais lattices |
| Crystallography: Orthorhombic-I lattice. One of the 14 Bravais lattices |
| Crystallography: Orthorhombic-P lattice. One of the 14 Bravais lattices. |
| Crystallography: Rhomobohedral lattice. One of the 14 Bravais lattices. |
| Crystallography: Rhomobohedral lattice. One of the 14 Bravais lattices. |
| Crystallography: Tetragonal-I lattice. One of the 14 Bravais lattices. |
| Crystallography: Tetragonal-P lattice. One of the 14 Bravais lattices. |
| Crystallography: Triclinic lattice |
| Crystallography: Unit cell of cementite (Fe_3C) |
| Crystallography: the crystal structure of carbon in its graphite form |
| Crystallography: the crystal structure of flourite CaF_2 |
| Crystallography: the crystal structure of gamma double-prime, nickel superalloys |
| Crystallography: the crystal structure of gamma in nickel based superalloys |
| Crystallography: the crystal structure of gamma prime, nickel based superalloys |
| Crystallography: the crystal structure of zinc sulphide (cubic-F form) |
| Design of High-Strength Bainitic Steels |
| Elementary Thermodynamic Functions |
| Finite Element Analysis, Part 2 |
| Finite Element Analysis, Part I |
| Interface Response Functions |
| Introduction to Diffusion |
| Kinetics: Diffusion-Controlled Growth |
| Kinetics: Phase Field Modelling |
| Lecture on Allotriomorphic and Idiomorphic Ferrite in Steels |
| Lecture on Martensite in Steels, Part II |
| Location of carbon atom in tetrahedral interstice of ferrite |
| Martensite and Bainite: Bain Correspondence |
| Martensite and Bainite: Bain Correspondence |
| Martensitic Transformations, Part I |
| Mathematical Models and Novelty in Steels |
| Mechanism of the Bainite and Widmanstatten Ferrite Transformations in Steels |
| Microstructure of Steel Weld Metals |
| Modelling the Microstructure and Properties of Steel Weld Metals |
9 |
| Neural Networks in Materials Science |
| Overall Transformation Kinetics |
| Phenomenological Theory of Martensite in Steels |
| Shape of Growing Crystals |
| Strong Steel Wires |
| TRIP-assisted steels: role of retained austenite |
| The crystal structure of Cu-Zn brass |
| The crystal structure of carbon in its diamond form |
| Thermodynamic Equilibrium between Solutions |
| Thermodynamic Models of Solutions |
| Thermodynamics of Diffusion |
| Thermodynamics of Irreversible Processes |
| Thermodynamics of Mechanical Alloying |
| Thermodynamics: Quasichemical Solution Model |
